Glass jar handling system

ABSTRACT

A system for use in depalletizing glass jars disposed in groups in a vertical stack wherein the groups of jars are successively moved laterally off the top of the stack and onto a lateral conveyor. The jars are supported on flat panels and a sensor is provided to sense the uppermost panel and to control the elevation of the stack, whereby the elevation will stop when the upper group of jars is aligned with the conveyor. Means is provided to push the jars away from alignment with the sensor so that it will engage the uppermost jar-supporting panel rather than the jars themselves. Means is also provided to push the upper panel laterally to assure that it will be in position to engage the sensor.

I United States Patent 91 n 11 3,724,686 Nelson [451 Apr. 3, 1973 [54] GLASS JAR HANDLING SYSTEM Primary Examiner-Gerald M. Forlenza Assistant Examiner-George F. Abraham [75] Inventor. Lloyd A. Nelson, Fremont, Mich. Attorney-Townsend & o d [73] Assignee: Gerber Products Company,

Freemont, Mich. 57 ABSTRACT Filed: 23, 1971 A system for use in depalletizing glass jars disposed in [21] APPL No: 173,387 groups in a vertical stack wherein the groups of jars are successively moved laterally off the top of the stack and onto a lateral conveyor. The jars are sup- [52] US. Cl ..-....2l4/8.5 A, 214/85 F pol-ted on flat panels and a sensor i provided to sense [51] [Ill- Cl ..B65g 59/02 the uppermost panel and to control e elevation of [58] Field Of Search ..2l4/8.5 A, 8.5 F h stack whereby the elevation will stop when the upper group of jars is aligned with the conveyor. [56] I Reiereuces Cited Means is provided to push the jars away from align- UNITED STATES PATENTS ment with the sensor so that it will engage the uppermost jar-supporting panel rather than the jars them- 3,107,794 10/1963 --Bechtold ..214/8.5 A selyes Means is also provided to the upper panel 3,180,499 4/1965 Wildheim ..2l4/8.5 A

laterally to assure that it will be in position to engage the sensor.

14 Claims, 10 Drawing Figures PATENTEDAPR3 I975 SHEET 1 or g i H x FlG .1

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sum 5 or 6 I N VENTOR.

LLOYD A. NELSON BY ATTORNEYS PATENTEUAPR 3 I973 sum 6 0r 5 INVENTOR.

LLOYD A. NELSON ATTORNEYS GLASS JAR HANDLING SYSTEM This invention relates to improvements in the handling of glass jars in volume and, more particularly, to a system for separating stacked groups of glass jars from a pallet.

Prepared baby foods are oftentimes packaged in relatively small glass jars of various volumes, representative volumes being denoted by 3% oz., oz., 6% oz., and 8 oz. In a jar-filling operation, many such glass jars must be readied for use. A preferred way of handling the jars and transporting then to a filling plant is to place groups of jars on a number of panel dividers and to stack the jar-laden dividers on a conventional pallet. For instance, for a 5 oz. jar, there would be 483 jars on each panel divider and 26 layers or groups of jars can be disposed on a pallet. Therefore, each pallet would support 12,558 jars and 16 such pallets can be placed in a van for moving the jars to the filling plant. Thus, the van can carry a total of 200,928 jars. It can be seen, therefore, that many jars are actually transported to a filling plant.

Conventional systems for handling pallets of such jars have been made to cause the groups of jars to be moved successively and incrementally upwardly so that the top group of jars in a stack can be moved laterally onto a conveyor. Thus, each group of jars can be moved onto a discharge conveyor as its panel divider is aligned with the conveyor.

To stop the uppermost panel divider in alignment with the conveyor, conventional equipment has a sensor which projects into the path of the panel divider and engages its upper surface. The sensor serves to actuate a switch which controls the elevator drive for the pallet. The problem which arises, however, with theuse of this sensor is that it oftentimes engages the jars on the uppermost panel divider rather than the divider itself. Thus, the panel divider stops below the conveyor rather than in alignment with it.

The present invention provides an improvement for such depalletizing equipment by providing means for assuring that none of the jars on the uppermost divider panel engage the sensor as the pallet is incrementally elevated. This is accomplished by moving certain jars out of alignment with the sensor, leaving the adjacent upper surface portion of the uppermost panel divider free to be engaged by the sensor. Thus, the sensor will sense the panel divider to effect the stopping of the elevation of the pallet so that the uppermost jars can be swept laterally off the divider and onto the discharge conveyor. Then, an operator can lift off the uppermost panel divider, following which the next incremental elevation of the pallet can occur.

Another aspect of the invention is to provide one or more pusher arms for pushing a panel divider near the top of the stack laterally through a sufficient distance to assure that the panel divider will be in position to be engaged by the sensing finger. This is necessary because the panel dividers on a pallet may not be truly vertically aligned with each other and must be properly oriented to engage the sensor. Otherwise, the elevation may not stop when the upper most panel divider is aligned with the discharge conveyor.

The primary object of this invention is to provide an improved jar handling system of the type having depalletizing capabilities including a sensor for engaging the uppermost panel divider supporting one of a group of vertically stacked jars on a vertically movable pallet. Means is provided to move the jars on the uppermost panel divider to clear the upper surface portion thereof which is aligned with the sensor so that the latter will engage the uppermost panel divider rather than the jars themselves to effect the stopping of the elevation of the panel at a location permitting the uppermost jars to be moved onto a lateral conveyor aligned with the uppermost divider.

A further object of this invention is to provide a system of the type described wherein each panel divider is pushed laterally and against an abutment before it becomes aligned with the discharge conveyor so that the panel divider will be aligned with the sensor to engage the same as the pallet is incrementally elevated.

Other objects of this invention will become apparent as the following specification progresses, reference being had to the accompanying drawings for an illustration of the invention.

IN THE DRAWINGS:

FIG. 1 is a side elevational view of a jar handling system including an elevator for a pallet containing stacked layers of jars, a lateral discharge conveyor near the upper end of the elevator and a pusher arm for sweeping the uppermost layer of glass jars in the stack onto the takeoff conveyor;

FIG. 2 is a top plan view of the system of FIG. 1;

FIG. ,3 is an enlarged, fragmentary top plan view of a sensing finger to sense the panel divider supporting the uppermost layer of glass jars;

FIG. 4 is a fragmentary front elevational view of the jar shifting mechanism below the sensing finger of FIG. 3;

FIG. 5 is a side elevational view of the mechanism of FIG. 4, showing the operative and retracted positions thereof;

FIG. 6 is a view similar to FIG. 3 but showing the retracted position of the mechanism of FIGS. 4 and 5',

FIG. 7 is a view similar to FIG. 6 but showing the jar shifting position of the mechanism;

FIG. 8 is a schematic view of the portion of the system near the upper end of the elevator, showing the jar shifting mechanism and a device for shifting a panel divider toward the shifting mechanism;

FIG. 9 is an enlarged, fragmentary side elevational view of the pusher mechanism; and

FIG. 10 is a rear elevational view of the pusher mechanism.

The glass jar handling system with which the improvements of the present invention are utilized is of the type shown in FIG. 1 and includes a first infeed conveyor 10, a second, relatively short conveyor 12 aligned with infeed conveyor 10 and disposed at the bottom of an elevator bin 14 having a front wall 16 and a rear opening 18 extending upwardly from below the planes of conveyors I0 and 12 to a backstop 19 hereinafter described. A pair of outwardly flared side strips 21 (FIGS. 1 and 2) embrace opening 18 and serve to funnel an incoming stack of jars on a pallet advanced toward conveyor 12 by conveyor la.

A discharge conveyor 20 is adjacent to and projects laterally from the upper end of elevator bin 14, and a second discharge take-away conveyor 22 is horizontally aligned with conveyor 20 but extends at right angles thereto. An elevating mechanism 13 shown only partially in FIG. 1, operates in bin 14 to move incrementally upwardly so that a pallet containing vertically stacked groups ofjars on mechanism can be moved upwardly, in stepwise fashion, mechanism 13 stopping each time the uppermost group of jars can be swept laterally onto conveyor 20 by sweep arm means 24. When all of the jars have been removed in this manner from the pallet, mechanism 13 is lowered and thus returns it to its initial position shown in FIG. 1 in horizontal alignment with infeed conveyor 10.

The system thus described is adapted to be utilized to depalletize glass jars 25 (FIG. 2) disposed in stacked layers on a conventional pallet, each layer of glass jars being disposed and supported on a panel divider 26 (FIG. 3, 7 and 8) with each divider being supported by the layer of glass jars therebelow and the lowermost divider supported on the pallet itself. The pallet with the stack of glass jars thereon can be loaded on infeed conveyor 10 in any suitable manner, conveyor 10 being operated to advance the loaded pallet toward and onto elevator bin conveyor 12, whereupon the pallet is incrementally elevated to successively position the uppermost layers of glass jars in position to be swept laterally and onto discharge conveyor 20 as the divider panel for the uppermost jars remains in the bin. The divider panel at the uppermost level can then be manually lifted off the stack by an operator, following which the elevating conveyor can move again through the incremental distance necessary to advance the various layers of jars successively into horizontal alignment with conveyor 20.

The elevation of mechanism 13 is operator controlled and the operator can observe when the upper layer of glass jars has been swept onto conveyor 20. He can then actuate the power means of mechanism 13 for elevating the latter once again. Sweep arm means 24 has a laterally shiftable sweep arm plate 28 coupled in any suitable manner to fluid-actuated power structure 30 (FIG. 8) which reciprocates the plate from right to left and then the plate is returned to the right when viewing FIG. 8.

When the empty pallet is lowered, it is brought into horizontal alignment with an empty pallet discharge conveyor 32 (FIG. 1) and the latter conveyor advances the same to a side transfer mechanism (not shown) then into an empty pallet stacker for stacking in an orderly fashion. As an empty pallet moves to the left when viewing FIG. 1 onto conveyor 32, a loaded pallet with glass jars thereon can be moved from infeed conveyor 10 onto elevator bin conveyor 12 to prepare for the next depalletizing operation.

The system thus far described utilizes one or more sensors 34 near the upper end of elevator bin 14. The purpose of each sensor is to sense the upper surface of the uppermost divider 26 and, since the sensor is in horizontal alignment with the upper stretch of discharge conveyor 20, it follows that the uppermost divider panel, when it is sensed by the sensor, will also be in horizontal alignment with the upper stretch of discharge conveyor 20. Sensor 34 is coupled mechanically by a shaft 36 to a limit switch 38 (FIG. 4 and the limit switch being operable to control a hydraulic circuit which gages travel of mechanism 13. The sensor is slightly movable upwardly so that the limit switch is actuated to de-energize mechanism 13 and to stop its elevation when the uppermost divider panel is in horizontal alignment with the upper stretch of conveyor 20. Then, the operator actuates power structure 30 causing sweep arm plate 28 to sweep the jars on the uppermost divider 26 laterally and onto a discharge conveyor 20.

It has been found that the jars on the uppermost divider panel may sometimes engage sensor 34 during the elevation of the uppermost layer, and when this occurs, the sensor is shifted upwardly to cause premature deactuation of the hoist. This will occur, of course, before the divider is horizontally aligned with the upper stretch of conveyor 20. To avoid this problem, one of the improvements of the present invention provides a jar shifting mechanism 40 (FIGS. 4-7) which includes a jar shifting member 42 mounted on the upper end of an arm 44 whose lower end is pivotally mounted by bearing 46 on a generally horizontal shaft 48 rigidly secured by mounts 50 in any suitable manner to the adjacent front wall 16 defining a part of elevator bin 14. Arm 44 has a lateral extension 52 (FIG. 5) secured to its lower end, extension 52 projecting away from shaft 48. The outer end of extension 52 has a clevis 54 which is coupled to the outer end of a piston rod 56 of a fluid piston and cylinder assembly 58. The opposite end of the cylinder 60 of assembly 58 is pivotally secured by a pin 62 on structure 64 also rigid to front wall 16. Actuation of assembly 58 causes the piston rod 56 to move outwardly of cylinder 60 and this causes the cylinder to pivot about pin 62 from the full line position of FIG. 5 to the dashed line position thereof. This causes extension 52 and thereby arm 44 to pivot about shaft 50, causing member 42 to move from the right hand side (FIG. 5) of wall 16 through an opening 66 therein to the lefthand side as shown in dashed lines in FIG. 5.

As member 42 moves in the foregoing manner, it shoves any jars in its path away from the adjacent edge of the corresponding divider 26, thus leaving a portion of the upper surface of the divider clear of any jars. As shown in FIG. 3, member 42 is directly below sensor 34 so that the cleared portion of the upper surface of the uppermost divider 26 will engage the sensor as the divider is elevated by mechanism 13.

Member 42 has a convex outer surface 68 as shown in FIGS. 3, 4, 6 and 7 to facilitate movement of the adjacent jars. Also, the vertical length of member 42 is short enough to prevent it from engaging the divider as it shoves the jars inwardly of the adjacent edge of the divider. This assures that member 42 will not be stopped prematurely before the jars have been moved through the proper distance.

Means is provided adjacent to elevator bin 14 to shove one or more of the upper dividers 26 to the left when viewing FIGS. 1 and 8 or toward and into engagement with front wall 16. The purpose of this feature is to assure that the uppermost divider is sufficiently close to front wall 16 such that an upper surface portion of the uppermost divider will be vertically aligned with sensor 34. Oftentimes the various dividers in the stack on the pallet are not in true vertical alignment with each other. Also, some dividers may be too far from wall 16 to permit them to engage the sensor.

To avoid this problem, a number of pusher bars 70 are mounted for pivotal movement on backstop 19 near the upper end of elevator bin 14 as shown in FIGS. 8-10. Each bar 70 has an offset extension 72 (FIGS. 9 and 10) which is rigidly secured to a shaft 74 mounted by a number of bearings 76 on the rear face of backstop 19. One of the bearings 76 is shown in FIGS. 9 and I0. Backstop 19 has openings 78 therein for pusher bars 70, respectively, to permit the bar to extend into bin 14. The width of each bar is such as to cause it to extend a distance into bin 14 sufficient to engage and push an adjacent divider 26 toward and against front wall 16. Thus, this wall acts as an abutment to limit the horizontal movement of the divider.

The pusher bars 70 are moved simultaneously by the rotation of shaft 74 through a small arc under the influence of a double acting fluid-actuated power assembly 80. To this end, assembly 80 has a cylinder 82, one end of which is pivotally coupled by a pin 84 to the rear face of backstop 19. A piston within the cylinder has a rod 86 which projects outwardly from the cylinder and is pivotally coupled by a pin 88 to one end of an arm 90 whose opposite end is rigidly secured to shaft 74. Thus, when rod 86 is forced into cylinder 82, the effective length of assembly 80 decreases, thereby causing shaft 74 to rotate in a counterclockwise sense.

- This causes pusher bars 70 to move simultaneously through respective openings 78 and against the adjacent edge of a divider 26 to urge the latter toward and into engagement with front wall 16. When rod 86 moves outwardly of cylinder 82, shaft 74 is rotated in a clockwise direction to cause the pusher bars to retract. To limit the rearward movement of the pusher bars when the same are retracted, backstop 19 has a rear overhang 92 (FIG. 10) provided with an inclined rear extension 94 in the path of the upper end of each pusher bar 70. Also, to limit the forward travel of the pusher bars, each bar 70 has a rear plate 96 thereon for engaging the rear face of backstop 19 when the bar has moved through the desired maximum distance into bin 14. Thus, plates 96 serve as stops. Generally, pusher bars 70 will be operable to engage and push the divider second from the top. However, more than one divider can be pushed, if desired.

FIG. 8 illustrates in a schematic form the fluid source 98 for supplying fluid under pressure to power devices 30, 58 and 80. Source 98 is controlled by the operator of the system which includes a pump 100 and a valve 102 for controlling fluid under pressure emanating from a fluid tank 104. Source 98 is controlled in a manner such that fluid is supplied to power devices 58 and 80 simultaneously to cause inward movements of member 42 and pusher bars 70. Also, member 42 and the pusher bars are retracted at the same time.

OPERATION The system is placed in operation when a full pallet is placed on in-feed conveyor 10. Such a pallet may contain 26 layers of glass jars to be unloaded or de-palletized. Conveyor 10 is advanced under the control of the operator of the system and additional pallets can be placed several feed apart on this conveyor.

As the conveyor advances, the lead pallet enters elevator bin 14. Sometimes, a full pallet of jars may be slightly out of perpendicular and, to offset this problem, bin 14 may have side plates which straighten the stack as it enters bin 14. The full pallet, when completely in bin 14, engages front wall 16 and is halted thereby. As the pallet enters the bin, member 42 and the pusher bars are in their retracted positions. Also, plate 28 is in its retracted position shown in FIG. 8. Divider 26 will be on the top of the full stack. Thus, when mechanism 13 is energized, this top divider will engage sensor 34, causing the latter to stop the mechanism, whereupon the operator then actuates source 98 to effect the movement of member 42 and the pusher bars into bin 14. Member 42 moves the adjacent jars 25 to clear a portion of the upper surface of the divider of the first layer of jars. Simultaneously, the pusher bars move the last-mentioned divider against the inner face of front wall 16. Simultaneously with these actions, plate 28 is swept over the top divider and then returned to its retracted position. As plate 28 is retracted, member 42 and the pusher bars are also retracted. The top divider is then manually removed and placed on an accumulation conveyor (not shown) for movement away from the top of the bin.

The operator then actuates mechanism 13 to elevate the pallet until the top divider engages sensor 34. This causes the elevation to stop and the operator actuates source 98 to again effect inward movement of member 42 and pusher bars for the same purpose as mentioned above. Simultaneously with these actions, plate 28 sweeps the uppermost layer of jars laterally and onto conveyor 20, there being a bridging or dead plate (not shown) between the upper stretch of the conveyor and the upper divider 26. The jars on the second layer are pushed inwardly by member 42 and the second divider is forced toward wall 16. As plate 28 is retracted, member 42 and the pusher bars are retracted also. The foregoing steps are repeated until the pallet is in the second layerposition at which time the power devices 58 and are overpowered by the pallet, signalling to the operator that the jars have all been removed from the pallet. Mechanism 113 is then lowered until it is at the bottom end of its path of travel. Conveyors l0 and 12 are then simultaneously actuated, the empty pallet moving onto discharge conveyor 32 and a full pallet moving onto conveyor 12 from conveyor 10. The foregoing process can be continued until all of the full pallets have been unloaded. Also, the collection of the empty pallets can be such that they are returned to a station from which they can be loaded onto the van and returned to the loading plant.

' I claim:

1. In a system for unloading a plurality of articles arranged in layers on respective panel dividers disposed in a vertical stack; means defining an elevator bin for receiving the stack; means adjacent to said bin for moving said stack thereinto; an actuatable elevating mechanism for incrementally elevating the stack; a sensor disposed adjacent to the upper end of the bin for sensinga divider; said sensor being "coupled to said mechanism for effecting the deactuation thereof when an upper surface portion of a divider is sensed by said sensor; a conveyor extending laterally from the uppermost end of the bin; first means adjacent to said upper end of the bin for sweeping the uppermost layer of articles into said actuatable conveyor; second actuatable means adjacent to and below the sensor for moving certain of the articles away from the upper surface portion of a divider aligned with the sensor, to thereby expose said surface portion for sensing by said sensor; and means coupled with said first means and said second means for controlling the actuation thereof.

2. In a system as set forth in claim 1, wherein said controlling means includes structure operable to actuate said first means and said second means simultaneously after said mechanism has been deactuated under the influence of said sensor.

3. In a system as set forth in claim 1, wherein said bin defining means includes a wall having an, opening therethrough, said second means being normally on one side of the wall exteriorly of the bin and movable through the opening and at least partially into said bin.

4. In a system as set forth in claim 1, wherein said second means includes an article-engaging member, and means mounting the member adjacent to said upper end of the bin for pivotal movement into and out of said bin.

5. In a system as set forth in claim 4, wherein said member has a convex, outer, article-engaging surface, said mounting means including an arm having a lower end and an upper end with the lower end being mounted for rotation about a generally horizontal axis, said member being secured to the upper end of the arm, and a power device coupled with said arm for moving the same in opposed directions about said axis.

6. In a system as set forth in claim 1, wherein said defining means includes a pair of spaced, generally vertical walls, said sensor being disposed at the upper end of one of the walls, said second means being shiftably mounted on said one wall and movable into the bin, and including means carried by the other wall and engageable with a divider and for urging the same toward said one wall.

7. In a system as set forth in claim 6, wherein said other wall has a number of openings therethrough said urging means includes a number of pusher bars, there being a pusher bar for each opening, respectively, means mounting each pusher bar for pivotal movement about a generally horizontal axis from a retracted position exteriorly of said bin to an operative position extending at least partially into the bin, and third actuable means coupled with the pusher bars for moving the same together in opposed directions between said positions thereof.

8. In a system as set forth in claim 7, wherein each of said first means, said second means, and said third means includes a respective, actuatable power device, said controlling means including structure for simultaneously actuating the power devices.

9. In a system for unloading a plurality of glass jars arranged in layers on respective panel dividers disposed on a pallet in a vertical stack: means including a pair of spaced, vertical walls for defining an elevator bin, said bin adapted to receive said pallet loaded with said stack of jars thereon; a first horizontal conveyor adjacent to the lower end of the bin for moving said loaded pallet thereinto; an actuatable elevating mechanism within said bin for supporting the loaded pallet and for incrementally elevating the same in said bin; a sensor adjacent the upper end of the bin and overlying a portion of the bin, said sensor being coupled with the elevating mechanism to effect the deactuation of the same when the sensor is engaged by an upper surface portion of a divider panel; a second horizontal conveyor adjacent to and extending laterally from said upper end of the bin; a sweep plate means mounting said sweep plate for movement across said upper end of the bin and along a horizontal path sufficiently close to the uppermost divider of said stack to sweep the jars off the last-mentioned divider and onto said second conveyor; a first actuatable power device coupled with said sweep plate for reciprocating the same along said horizontal path; a jar engaging member; means shiftably mounting said member on one of said walls adjacent to said upper end of the bin and below and in vertical alignment with said sensor, said member being movable from a retracted position and of the vertical path of travel of the stack into an operative position partially in said vertical path and through a distance sufficient to move certain of the jars on the adjacent divider inwardly of the bin to expose an upper surface portion on the last-mentioned divider, whereby said upper surface portion will engage said sensor as said stack is incrementally elevated by said mechanism; a second actuatable power device coupled with said member for reciprocating the same relative to said one wall; a number of pusher bars; means mounting the pusher bars on the other wall adjacent to said upper end of the bin for movement together into engagement with an adjacent divider and through a distance sufficient to urge the last-mentioned divider toward said one wall; a third actuatable power device coupled with said pusher bars for reciprocating the same relative to said other wall; and means coupled with said power devices for simultaneously actuating the same when said elevating mechanism has been deactuated under the influence of said sensor.

10. In a system of the type for unloading a plurality of articles arranged in layers on respective panel dividers in a generally vertical stack supported on and being incrementally elevated by an actuatable elevating mechanism in an elevator bin with the uppermost layer of articles being swept laterally onto a discharge conveyor near the upper end of the bin after a corresponding incremental elevator of the stack, the improvement comprising: a sensor mounted near the upper end of the bin for sensing an upper surface portion of the uppermost divider of said stack, said sensor adapted to be coupled with said elevating mechanism to effect the deactuation thereof when said sensor senses an upper surface portion of the uppermost divider of said stack; means adapted to be mounted below and in alignment with the sensor for moving the adjacent articles on a second divider below said uppermost divider with the movement of the articles being sufficient to expose the upper surface portion of the second divider aligned with the sensor, whereby said exposed upper surface portion will engage the sensor as the stack is incrementally elevated.

11. In a system as set forth in claim 10, wherein said moving means includes a jar-engaging member means mounting the member for pivotal movement about a generally horizontal axis, and power means coupled with the member for pivoting the same about said axis.

12. In a system of the type for unloading a plurality of articles arranged in layers on respective panel dividers in a generally vertical stack supported on and being incrementally elevated by an actuatable elevating mechanism in an elevator bin with the uppermost layer of articles being swept laterally onto a discharge conveyor near the upper end of the bin after a corresponding incremental elevation of the stack, the improvement comprising: a sensor adapted to be mounted on one side of the bin near the upper end thereof for sensing an upper surface portion of the uppermost divider of said stack, said sensor adapted to be coupled with said elevating mechanism to effect the deactuation of the same when said sensor senses an upper surface portion of the uppermost divider of said stack; means adapted to be mounted below and in alignment with the sensor for moving the adjacent articles on a second divider below said uppermost divider with the movement of said adjacent articles being sufficient to e pose the upper surface portion of the second divide aligned with the sensor, whereby said exposed upp r surface portion will engage the sensor as the stack is incrementally elevated; and means adapted to'be mounted on the opposite side of the bin for engaging the second divider and for pushing the same toward said one side of the bin.

13. In a system as set forth in claim 12, wherein said moving means includes a jar-engaging member, means mounting the member for pivotal movement about a first generally horizontal axis and a first actuatable power device coupled with the member for pivoting the same about said first axis, said pushing means including a number of pusher bars, means mounting said pusher bars for rotation together about a second, generally horizontal axis, and a second actuatable power device coupled with the pusher bars for rotating the same about said second axis, and including control means coupled with said power devices for simultaneously actuating the same when said elevating mechanism has been deactuated under the influence of said sensor.

14. In a system as set forth in claim 13, wherein said member has a convex, outer, jar-engaging surface, each pusher bar having an elongated, generally vertical outer face for engaging the proximal edge of the second divider. 

1. In a system for unloading a plurality of articles arranged in layers on respective panel dividers disposed in a vertical stack; means defining an elevator bin for receiving the stack; means adjacent to said bin for moving said stack thereinto; an actuatable elevating mechanism for incrementally elevating the stack; a sensor disposed adjacent to the upper end of the bin for sensing a divider; said sensor being coupled to said mechanism for effecting the deactuation thereof when an upper surface portion of a divider is sensed by said sensor; a conveyor extending laterally from the uppermost end of the bin; first means adjacent to said upper end of the bin for sweeping the uppermost layer of articles into said actuatable conveyor; second actuatable means adjacent to and below the sensor for moving certain of the articles away from the upper surface portion of a divider aligned with the sensor, to thereby expose said surface portion for sensing by said sensor; and means coupled with said first means and said second means for controlling the actuation thereof.
 2. In a system as set forth in claim 1, wherein said controlling means includes structure operable to actuate said first means and said second means simultaneously after said mechanism has been deactuated under the influence of said sensor.
 3. In a system as set forth in claim 1, wherein said bin defining means includes a wall having an opening therethrough, said second means being normally on one side of the wall exteriorly of the bin and movable through the opening and at least partially into said bin.
 4. In a system as set forth in claim 1, wherein said second means includes an article-engaging member, and means mounting the member adjacent to said upper end of the bin for pivotal movement into and out of said bin.
 5. In a system as set forth in claim 4, wherein said member has a convex, outer, article-engaging surface, said mounting means including an arm having a lower end and an upper end with the lower end being mounted for rotation about a generally horizontal axis, said member being secured to the upper end of the arm, and a power device coupled with said arm for moving the same in opposed directions about said axis.
 6. In a system as set forth in claim 1, wherein said defining means includes a pair of spaced, generally vertical walls, said sensor being disposed at the upper end of one of the walls, said second means being shiftably mounted on said one wall and movable into the bin, and including means carried by the other wall and engageable with a divider and for urging the same toward said one wall.
 7. In a system as set forth in claim 6, wherein said other wall has a number of openings therethrough said urging means includes a number of pusher bars, there being a pusher bar for each opening, respectively, means mounting each pusher bar for pivotal movement about a generally horizontal axis from a retracted position exteriorly of said bin to an operative position extending at least partially into the bin, and third actuable means coupled with the pusher bars for moving the same together in opposed directions between said positions thereof.
 8. In a system as set forth in claim 7, wherein each of said first means, said second means, and said third means includes a respective, actuatable power device, said controlling means including structure for simultaneously actuating the power devices.
 9. In a system for unloading a plurality of glass jars arranged in layers on respective pAnel dividers disposed on a pallet in a vertical stack: means including a pair of spaced, vertical walls for defining an elevator bin, said bin adapted to receive said pallet loaded with said stack of jars thereon; a first horizontal conveyor adjacent to the lower end of the bin for moving said loaded pallet thereinto; an actuatable elevating mechanism within said bin for supporting the loaded pallet and for incrementally elevating the same in said bin; a sensor adjacent the upper end of the bin and overlying a portion of the bin, said sensor being coupled with the elevating mechanism to effect the deactuation of the same when the sensor is engaged by an upper surface portion of a divider panel; a second horizontal conveyor adjacent to and extending laterally from said upper end of the bin; a sweep plate means mounting said sweep plate for movement across said upper end of the bin and along a horizontal path sufficiently close to the uppermost divider of said stack to sweep the jars off the last-mentioned divider and onto said second conveyor; a first actuatable power device coupled with said sweep plate for reciprocating the same along said horizontal path; a jar engaging member; means shiftably mounting said member on one of said walls adjacent to said upper end of the bin and below and in vertical alignment with said sensor, said member being movable from a retracted position and of the vertical path of travel of the stack into an operative position partially in said vertical path and through a distance sufficient to move certain of the jars on the adjacent divider inwardly of the bin to expose an upper surface portion on the last-mentioned divider, whereby said upper surface portion will engage said sensor as said stack is incrementally elevated by said mechanism; a second actuatable power device coupled with said member for reciprocating the same relative to said one wall; a number of pusher bars; means mounting the pusher bars on the other wall adjacent to said upper end of the bin for movement together into engagement with an adjacent divider and through a distance sufficient to urge the last-mentioned divider toward said one wall; a third actuatable power device coupled with said pusher bars for reciprocating the same relative to said other wall; and means coupled with said power devices for simultaneously actuating the same when said elevating mechanism has been deactuated under the influence of said sensor.
 10. In a system of the type for unloading a plurality of articles arranged in layers on respective panel dividers in a generally vertical stack supported on and being incrementally elevated by an actuatable elevating mechanism in an elevator bin with the uppermost layer of articles being swept laterally onto a discharge conveyor near the upper end of the bin after a corresponding incremental elevator of the stack, the improvement comprising: a sensor mounted near the upper end of the bin for sensing an upper surface portion of the uppermost divider of said stack, said sensor adapted to be coupled with said elevating mechanism to effect the deactuation thereof when said sensor senses an upper surface portion of the uppermost divider of said stack; means adapted to be mounted below and in alignment with the sensor for moving the adjacent articles on a second divider below said uppermost divider with the movement of the articles being sufficient to expose the upper surface portion of the second divider aligned with the sensor, whereby said exposed upper surface portion will engage the sensor as the stack is incrementally elevated.
 11. In a system as set forth in claim 10, wherein said moving means includes a jar-engaging member means mounting the member for pivotal movement about a generally horizontal axis, and power means coupled with the member for pivoting the same about said axis.
 12. In a system of the type for unloading a plurality of articles arranged in layers on respective panel dividers in a generally vertical stack supported on and being incrementally elevated by an actuatable elevating mechanism in an elevator bin with the uppermost layer of articles being swept laterally onto a discharge conveyor near the upper end of the bin after a corresponding incremental elevation of the stack, the improvement comprising: a sensor adapted to be mounted on one side of the bin near the upper end thereof for sensing an upper surface portion of the uppermost divider of said stack, said sensor adapted to be coupled with said elevating mechanism to effect the deactuation of the same when said sensor senses an upper surface portion of the uppermost divider of said stack; means adapted to be mounted below and in alignment with the sensor for moving the adjacent articles on a second divider below said uppermost divider with the movement of said adjacent articles being sufficient to expose the upper surface portion of the second divider aligned with the sensor, whereby said exposed upper surface portion will engage the sensor as the stack is incrementally elevated; and means adapted to be mounted on the opposite side of the bin for engaging the second divider and for pushing the same toward said one side of the bin.
 13. In a system as set forth in claim 12, wherein said moving means includes a jar-engaging member, means mounting the member for pivotal movement about a first generally horizontal axis and a first actuatable power device coupled with the member for pivoting the same about said first axis, said pushing means including a number of pusher bars, means mounting said pusher bars for rotation together about a second, generally horizontal axis, and a second actuatable power device coupled with the pusher bars for rotating the same about said second axis, and including control means coupled with said power devices for simultaneously actuating the same when said elevating mechanism has been deactuated under the influence of said sensor.
 14. In a system as set forth in claim 13, wherein said member has a convex, outer, jar-engaging surface, each pusher bar having an elongated, generally vertical outer face for engaging the proximal edge of the second divider. 